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During glucose breakdown, glycolysis and fermentation occur anaerobically. Glycolysis breaks a glucose molecule into energy and pyruvate. Fermentation uses to the pyruvate to form either ethanol or lactate.
When muscle cells undergo anaerobic respiration they become fatigued and painful due to the buildup of pyruvate in cells. The pyruvate is converted to lactic acid.
Anaerobic glycolysis produces lactate, aerobic glycolysis produces pyruvate.
It doesn't break down glucose per se. It breaks down the pyruvate produced from glycolysis into lactate. Only the liver has the ability to convert lactate back to pyruvate.
There are dozens of compounds associated with anaerobic respiration; two of these are pyruvate and lactic acid.
it is to produce ATP from the pyruvate which would have bin produced in the cytoplasm during anaerobic respiration
it is to produce ATP from the pyruvate which would have bin produced in the cytoplasm during anaerobic respiration
During glucose breakdown, glycolysis and fermentation occur anaerobically. Glycolysis breaks a glucose molecule into energy and pyruvate. Fermentation uses to the pyruvate to form either ethanol or lactate.
Lactic acid
When muscle cells undergo anaerobic respiration they become fatigued and painful due to the buildup of pyruvate in cells. The pyruvate is converted to lactic acid.
Anaerobic glycolysis produces lactate, aerobic glycolysis produces pyruvate.
It doesn't break down glucose per se. It breaks down the pyruvate produced from glycolysis into lactate. Only the liver has the ability to convert lactate back to pyruvate.
There are dozens of compounds associated with anaerobic respiration; two of these are pyruvate and lactic acid.
energy
Glycolysis itself anaerobic process and forms pyruvate. If there is oxygen present, pyruvate is reduced to acetyl-coenzyme A; if there is no oxygen present, pyruvate goes through fermentation, forming either lactic acid or ethanol.
No, pyruvate is a molecule produced from the breakdown of glucose during glycolysis.
Answer During Glycolysis NAD+ accepts a pair of high-energy electrons and becomes NADH.